Signal transmission processing method and apparatus and distributed base station

ABSTRACT

The disclosures provide a method and apparatus for transmitting and receiving interface signals of a distributed base station. At least one channel of Common Public Radio Interface (CPRI) signals of a distributed base station are encapsulated into optical transport unit x (OTUx) signals in a frame structure of OTUx by adopting Generic Mapping Procedure (GMP) mapping scheme, wherein the x represents a transmission capacity and wherein the OTUx is adopted for providing a bandwidth required by the at least one channel of CPRI signals, and then the OTUx signals that bear the at least one channel of CPRI signals are sent.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.13/287,830, filed on Nov. 2, 2011, which is a continuation ofInternational Application No. PCT/CN2009/072937, filed on Jul. 27, 2009,all of which are hereby incorporated by reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to the field of communicationstechnologies, and in particular, to a method and apparatus fortransmitting and receiving interface signals of a distributed basestation.

BACKGROUND

The 2 G/3 G radio network based access system includes a core network(CN), a radio access network (such as a Universal Terrestrial RadioAccess Network (UTRAN)), and user equipment (UE), where the radio accessnetwork includes a radio network controller (RNC) and a radio basestation (or referred to as Node B), and a distributed base station is animportant form of the radio base station. As shown in FIG. 1, adistributed base station includes a base band unit (BBU) and a remoteradio unit (RRU). The interface of the radio distributed base station isa bus interface between the BBU and the RRU, where the bus interface isgenerally an optical interface or may be an electrical interface. TheBBU is a small-sized box-type device; the RRU is an outdoor remote radiodevice, which is mounted directly on the metal mast or on the wall nearthe antenna. The interface between the BBU and the RRU is connected viaone or several specific signal links, and includes any of the threetypes: a Common Public Radio Interface (CPRI), IR interface, and OpenBase Station Architecture Initiative (OBSAI) interface, with themainstream rate more than 1228.8M. The interface of the distributed basestation in Time Division-Synchronous Code Division Multiple Access(TD-SCDMA) mode is the IR interface, for which each link is at ahigh-speed serial digital transmission rate. Currently, the commercialmainstream rate is 2457.6 Mb/s, which may, in the future, be 3.0720 Gb/sor higher. Transmission on the links for interface signals of radiodistributed base station between the BBU and the RRU is realized byconsuming optical fiber resources. The number of the channels ofinterface signals of the distributed base station which can be borne byoptical fiber influences the requirements on both optical fiberresources in the existing network during networking of the distributedbase station, and the costs of transmitting the interface signals of thedistributed base station. Transmission technology can impact theefficiency of operating and maintaining networks.

In the prior art, the Wavelength Division Multiplexing (WDM) technologyis applied for signal transmission between the BBU and the RRU. That is,as shown in FIG. 2, a WDM wavelength is adopted for each channel ofinterface signals of the distributed base station in the radio base bandpool of the BBU. The four channels of signals in FIG. 2 respectivelyadopt λ1, λ2, λ3, and λ4, which are transmitted after being processed byan optical wavelength splitting/merging module. At the remote radio unitof the receiving end, received optical signals are firstly processed bythe optical wavelength splitting/merging module, and then the separatedoptical signals are transmitted to the corresponding remote radiomodule. Due to attenuation of the optical signals transmitted in theoptical fiber, for the optical signals that need to pass longtransmission distance, an optical amplifier can be added in the opticalpath to amplify the optical signals during transmission. In this way,longer transmission distance can be realized, and system monitoring canbe performed by setting a system monitoring module in the system.

During the implementation of the present invention, the inventor findsthat: In the prior art, each channel of the interface signals of thedistributed base station needs to occupy an optical wavelength, whichleads to low transmission efficiency during transmission between the BBUand the RRU.

SUMMARY

The embodiments of the present invention provide a signal transmissionprocessing method and a signal transmission processing apparatus and adistributed base station to improve the efficiency of signaltransmission.

In order to achieve the above objectives, a signal transmissionprocessing method is provided in the present invention, including:

obtaining at least one channel of interface signals of a distributedbase station;

performing optical transport network (OTN) electrical layer multiplexingfor the obtained at least one channel of interface signals of thedistributed base station; and

performing electro-optic conversion for the signals obtained through OTNelectrical layer multiplexing to generate a channel of optical signalsand transmitting the signals.

A distributed-base-station-interface-signal transmission processingapparatus is provided in the present invention, including:

an obtaining module, configured to obtain at least one channel ofinterface signals of a distributed base station;

a multiplexing module, configured to perform OTN electrical layermultiplexing for the obtained at least one channel of interface signalsof the distributed base station; and

a first sending module, configured to perform electro-optic conversionfor the signals obtained through OTN electrical layer multiplexing togenerate a channel of optical signals and transmit the optical signals.

A distributed base station is further provided in the embodiments of thepresent invention, including: a BBU, an RRU, and an OTN processingmodule configured to accomplish a communication connection between theBBU and the RRU. The OTN processing module is configured to perform OTNelectrical layer multiplexing for the interface signals of thedistributed base station that are transmitted between the BBU and theRRU and transmit the signals.

By using the signal transmission processing method and the signaltransmission processing apparatus and the distributed base stationprovided in embodiments of the present invention, OTN electrical layermultiplexing is performed on at least one channel of interface signalsof the distributed base station, and electro-optic conversion isperformed for the signals obtained through OTN electrical layermultiplexing to generate a channel of optical signals for transmission.Therefore, multiple channels of interface signals of the distributedbase station are multiplexed into one channel of optical signals, andthe optical signals are transmitted between the BBU and the RRU of thedistributed base station, thereby improving the efficiency of signaltransmission.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a structure diagram of a distributed base station in the priorart;

FIG. 2A is a schematic diagram of transmitting interface signals of adistributed base station in the prior art;

FIG. 2B is a schematic diagram of transmitting interface signals of adistributed base station in the prior art;

FIG. 3 is a flowchart of a signal transmission processing methodaccording to an embodiment of the present invention;

FIG. 4 is a structure diagram of a signal transmission processingapparatus according to an embodiment of the present invention;

FIG. 5A is a first structure diagram of a distributed base stationaccording to an embodiment of the present invention;

FIG. 5B is a second structure diagram of a distributed base stationaccording to an embodiment of the present invention;

FIG. 6 is a networking structure when different optical transport units(OTUx) signal frames are adopted according to an embodiment of thepresent invention;

FIG. 7 is a schematic diagram of mapping interface signals to ODUkaccording to an embodiment of the present invention;

FIG. 8A is a flowchart of transmitting signals according to anembodiment of the present invention;

FIG. 8B is a flowchart of receiving signals according to an embodimentof the present invention;

FIG. 9 is a schematic diagram of the frame structure of OTUx accordingto an embodiment of the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The technical solutions of the present invention are further elaboratedin detail below with reference to accompanying drawings and embodiments.

The embodiments of the present invention provide a signal transmissionprocessing method. FIG. 3 is a flowchart of a signal transmissionprocessing method according to an embodiment of the present invention,including the following steps.

Step 101: Obtain at least one channel of interface signals of adistributed base station.

Step 102: Perform OTN electrical layer multiplexing for the obtained atleast one channel of interface signals of the distributed base station.

Step 103: Perform electro-optic conversion for the signals obtainedthrough OTN electrical layer multiplexing to generate one channel ofoptical signals and transmit the optical signals.

By using the signal transmission processing method according to theembodiment of the present invention, OTN electrical layer multiplexingis performed on at least one channel of interface signals of thedistributed base station, and electro-optic conversion is performed forthe signals obtained through OTN electrical layer multiplexing togenerate a channel of optical signals for transmission. Therefore,multiple channels of interface signals of the distributed base stationare multiplexed into one channel of optical signals, and the opticalsignals are transmitted between the BBU and the RRU of the distributedbase station, thereby improving the efficiency of signal transmission.

The signal transmission processing method provided in the embodiment ofthe invention can be applied in downlink data transmission, namely, inthe process of transmitting the signals from the BBU to the RRU; or canbe applied in uplink data transmission, namely, in the process oftransmitting the signals from the RRU to the BBU.

The interface signals of the distributed base station can be OBSAIinterface signals, CPRI interface signals, or IR interface signals,where: the IR interface is an interface of the distributed base stationin the TD-SCDMA mode. The above interface signals as a whole aredirectly encapsulated into OTN signal frames, and it is not required toperform de-encapsulating for the interface signals. The transmissionmode is a transparent transmission mode, which can reduce complexity ofprocessing signal and reduce costs. In the embodiments of the presentinvention, the OTN that is provided with higher transport bandwidth isadopted to transmit data, thereby providing higher data transmissionrate.

In downlink signal transmission, the obtaining at least one channel ofinterface signals of the distributed base station may be specifically:obtaining at least one channel of interface signals of the distributedbase station that are sent by at least one BBU.

In uplink signal transmission, the obtaining at least one channel ofinterface signals of the distributed base station may be specifically:obtaining at least one channel of interface signals of the distributedbase station that are sent by at least one RRU.

For the process of the uplink signal transmission and the process of thedownlink signal transmission, the processes may be the same.Specifically, the performing OTN electrical layer multiplexing for theobtained at least one channel of interface signals of the distributedbase station may be: encapsulating the interface signals of thedistributed base station into each OTN signal frame according to a rateof the received at least one channel of interface signals of thedistributed base station; the performing electro-optic conversion forthe signals obtained through OTN electrical layer multiplexing togenerate one channel of optical signals and transmitting the opticalsignals may be: performing electro-optic conversion for the OTN signalframes to generate one channel of optical signals and transmitting theoptical signals to an opposite end, particularly, transmitting throughan OTN or a directly-attached fiber. When the directly-attached fiber isused, in the signal transmission processing method, the OTN device isonly used to process signals to generate the OTN signal frames, anddirectly-attached fiber is used to transmit OTN signal frames.

In the downlink signal transmission, if the opposite end is an RRU, thesignal transmission processing method may further include the followingsteps: performing electro-optic conversion for received optical signalsand performing frame processing to obtain interface signals of thedistributed base station in each OTN signal frame; and transmitting theinterface signals of the distributed base station to a corresponding RRUthrough an optical interface or electric interface.

In uplink service data transmission, if the opposite end is a BBU, thesignal transmission processing method may further include the followingsteps: performing electro-optic conversion for the received opticalsignals and performing frame processing to obtain interface signals ofthe distributed base station in each OTN signal frame; and transmittingthe interface signals of the distributed base station to a correspondingBBU through an optical interface or electric interface.

A distributed-base-station-interface-signal transmission processingapparatus is provided in the embodiments of the present invention. FIG.4 is a structure diagram of a signal transmission processing apparatusaccording to an embodiment of the present invention. As shown in FIG. 4,the apparatus includes an obtaining module 11, a multiplexing module 12,and a sending module 13, where: the obtaining module 11 is configured toobtain at least one channel of interface signals of a distributed basestation, and the obtaining module in the embodiment of the presentinvention may be equivalent to an interface module for the interfacesignals of the distributed base station; the multiplexing module 12 isconfigured to perform OTN electrical layer multiplexing for the obtainedat least one channel of interface signals of the distributed basestation; and the sending module 13 is configured to performelectro-optic conversion for the signals obtained through OTN electricallayer multiplexing to generate one channel of optical signals andtransmit the optical signals.

By employing the distributed-base-station-interface-signal transmissionprocessing apparatus according to the embodiment of the presentinvention, OTN electrical layer multiplexing is performed for at leastone channel of interface signals of the distributed base station, andelectro-optic conversion is performed for the signals obtained throughOTN electrical layer multiplexing to generate one channel of opticalsignals for transmission. Therefore, multiple channels of interfacesignals of the distributed base station can be multiplexed into onechannel of optical signals and then transmitted between the BBU and theRRU of the distributed base station, thereby increasing efficiency ofsignal transmission.

The signal transmission processing apparatus according to the aboveembodiments of the present invention can be set at the BBU side or atthe RRU side. If the apparatus is set at the BBU side, the aboveobtaining module includes a first obtaining unit or a second obtainingunit, where the first obtaining unit is configured to obtain at leastone channel of interface signals of the distributed base station that issent by at least one BBU. If the apparatus is set at the RRU side, theabove obtaining module includes a second obtaining unit, where thesecond obtaining unit is configured to obtain at least one channel ofinterface signals of the distributed base station that are sent by atleast one RRU.

Moreover, with regard to an signal transmission processing apparatus setat either of the BBU side and the RRU side, the multiplexing moduletherein may include a first processing unit, configured to encapsulatethe interface signals of the distributed base station into respectiveOTN signal frames according to a rate of the received at least onechannel of interface signals of the distributed base station.

The signal transmission processing apparatus, set at either of the BBUside and the RRU side, can receive the optical signals sent by thesignal transmission processing apparatus at the opposite end. Therefore,a first signal processing module and a second sending module may be set,where: the first signal processing module is configured to performoptic-electro conversion for the received optical signals and performframe processing to obtain the interface signals of the distributed basestation in respective OTN signal frames; the second sending module isconfigured to send the interface signals of the distributed base stationto a corresponding RRU or BBU through an optical interface or anelectrical interface.

A distributed base station is further provided in the embodiments of thepresent invention. The distributed base station includes a BBU, an RRU,and an OTN processing module configured to accomplish a communicationconnection between the BBU and the RRU. The OTN processing module isconfigured to perform OTN electrical layer multiplexing for theinterface signals of the distributed base station that are transmittedbetween the BBU and the RRU and then transmit the signals multiplexed.

A distributed base station is provided in the embodiments of the presentinvention. The BBU or RRU or both of the BBU and the RRU may include theabove distributed-base-station-interface-signal transmission processingapparatus. The apparatus performs OTN electrical layer multiplexing forat least one channel of interface signals of the distributed basestation, and performs electro-optic conversion for the signals obtainedthrough OTN electrical layer multiplexing to generate one channel ofoptical signals and transmit the signals, thereby realizing to multiplexmultiple channels of interface signals of the distributed base stationinto one channel of optical signals and transmit the signals between theBBU and the RRU of the distributed base station so as to increase theefficiency of signal transmission.

In the downlink service data transmission, the OTN processing module mayfurther include a first OTN processing unit, a second OTN processingunit, and an OTN. The first OTN processing unit is configured to receiveat least one channel of interface signals of the distributed basestation that are sent by the BBU, and encapsulate the interface signalsof the distributed base station into OTN signal frames according to arate of the interface signals of the distributed base station andtransmit the signals multiplexed. The second OTN processing unit isconfigured to receive the signals sent by the first OTN processing unitthrough the OTN, perform optic-electro conversion and perform frameprocessing to obtain the interface signals of the distributed basestation in each OTN signal frame, and send the interface signals of thedistributed base station to a corresponding RRU through an opticalinterface or an electrical interface. The OTN is configured to send theOTN signal frames, which are generated through encapsulation by thefirst OTN processing unit, to the second OTN processing unit.

In transmission of the uplink service data, the second OTN processingunit is further configured to receive at least one channel of interfacesignals of the distributed base station that are sent by the RRU, andencapsulate the interface signals of the distributed base station intothe OTN signal frames according to a rate of the interface signals ofthe distributed base station and transmit the signals encapsulated; thefirst OTN processing unit is further configured to receive the signalssent by the second OTN processing unit through the OTN, performoptic-electro conversion and perform frame processing to obtain theinterface signals of the distributed base station in each OTN signalframe, and send the interface signals of the distributed base station toa corresponding BBU through an optical interface or an electricalinterface; and the OTN is further configured to send the OTN signalframes, which are generated through encapsulation performed by thesecond OTN processing unit, to the first OTN processing unit.

FIG. 5A is a first structure diagram of a distributed base stationaccording to an embodiment of the present invention, and FIG. 5B is asecond structure diagram of a distributed base station according to anembodiment of the present invention. The embodiment provides adistributed base station based on the OTN technology. As shown in FIG.5, the base station includes a BBU, an RRU, and an OTN processingmodule. The OTN processing module includes adistributed-base-station-interface-signal transmission processingapparatus at the BBU side, and adistributed-base-station-interface-signal transmission processingapparatus at the RRU side and a transmission link, where thetransmission link is an OTN or a directly-attached optical fiber. InFIG. 5A, a BBU is connected to a signal transmission processingapparatus. Multiple channels of interface signals of the distributedbase station that are sent by the BBU are firstly processed by the abovesignal transmission processing apparatus, and then the signals processedare transmitted through an optical fiber or OTN. Thedistributed-base-station-interface-signal transmission processingapparatus at the RRU side performs corresponding processing for receivedsignals, restores the interface signals of the distributed base station,and sends the interface signals to the RRU. FIG. 5B shows that two ormore BBUs correspond to one distributed-base-station-interface-signaltransmission processing apparatus.

The OTN technology according to the embodiments is a technology usinglarge-capacity transmission on the internet. It is suitable to be usedin bearer transmission of interface signals of the distributed basestation. The feature of large-capacity transmission of the OTN issuitable of adopting different signal frames for different transmissioncapacities. For example, OTU1, OTU2, OTU3, or OTU4 can be adopted, wherethe transmission capacity (size of the bandwidth) of OTU1 is 2.488 G,the transmission capacity of OTU2 is 9.95 G, four times as large as thatof OTU1, the transmission capacity of OTU3 is four times as large asthat of OTU2, and the transmission capacity of OTU4 is larger. Interfacesignals of the distributed base station may be encapsulated into OTU1signal frames, or OTU2 signal frames, or OTU3 signal frames, or evenOTU4 signal frames of the OTN. The current commercial bandwidth ofinterface signals of the distributed base station ranges from 600M to3.1 G. Typical commercial rates include: 768 Mbps, 1536 Mbps, and 3072Mbps which are required by the OBSAI; 614.4 Mbps, 1228.8 Mbps, and2457.6 Mbps which are required by the CPRI/IR. In future, a higher rate,such as 6 G to 10 G, may emerge. The signal frames such as OTU2 signalframes, OTU3 signal frames, and OTU4 signal frames of the OTN may beencapsulated and transmitted at any of the above transmission rates.Currently, a mainstream rate of interface signals of the distributedbase station has exceeded 1228.8M, which is suitable of adopting the OTNtransmission channel with large capacity.

FIG. 6 is a networking structure when different OTUx signal frames areadopted according to an embodiment of the present invention. As shown inFIG. 6, in downlink signal transmission, namely, when the signals aretransmitted from the BBU to the RRU, one or more BBUs include multiplechannels of interfaces of the distributed base station, and electricalsignals or optical signals of one or more channels of the interfaces ofthe distributed base station are transmitted to a signal transmissionprocessing apparatus, namely, the OTN processing unit. The above OTNprocessing unit is configured to perform OTN electrical layermultiplexing for the obtained interface signals of the distributed basestation. The following embodiment elaborates the details. If an opticalinterface is adopted, the OTN processing unit firstly performsoptic-electro conversion, then the signals are encapsulated into properOTN signal frames, and different containers are selected according todifferent rates of interface signals of the distributed base station.Take IR 2.4576 G for an example. One channel of IR 2.4576 G signals maybe selected to be encapsulated into one channel of OTU1, which is aspecial example of OTN electrical layer multiplexing in the embodimentof the present invention. That is, with regard to a case of one channelof IR interface signals, four channels of IR 2.4576 G signals areencapsulated into one channel of OTU2 and 16 channels of IR 2.4576 Gsignals are encapsulated into one channel of OTU3 to realizemultiplexing of interface signals of the distributed base station. Afterthe OTN signal frames are transmitted to the electro-optic module forelectro-optic conversion, the OTN signal frames are transmitted to thedownstream through an OTN or optical fiber network. The OTN processingunit receives the signals from the upstream, performs optic-electroconversion, performs frame processing for the OTN signals, and restoreseach channel of interface signals of the distributed base station fromOTU1, OTU2, and OTU3, etc. In the process of restoring the signals, theclock for each channel of interface signals of the distributed basestation may be independently restored at the same time. That is, afterbeing transmitted through the OTN or directly-attached optical fiber,each channel of the interface signals of the distributed base stationare restored through synchronous demultiplexing or asynchronousdemultiplexing, where electro-optic conversion may be performed for therestored interface signals of the distributed base station, and thesignals are transmitted to the RRU through an optical interface orelectrical interface.

Multiplexing and demultiplexing provided in the embodiment of thepresent invention may adopt a Generic Mapping Procedure (GMP) mappingscheme. As shown in FIG. 7, by using this method, the interface signalsof the distributed base station are directly multiplexed to an ODUkpayload area, and bit streams of the distributed base station aredirectly mapped to the D byte therein. Compared with the previous methodof GFP-T ensuplation that the signals are encoded through8B/10B and64/65B encoding and are multiplexed to STMx, intermediate encoding anddecoding, and GFP frame processing are omitted, and therefore thetransparency is higher.

As shown in FIG. 8A, the interface signals of the distributed basestation according to the embodiment of the present invention aremultiplexed by the multiplexing module to OTUx, and then the OTUxsignals are sent by an OTUx sending module. As shown in FIG. 8B, at thereceiving end, an OTUx receiving module receives the preceding OTUxsignals, the demultiplexing module demultiplexes the OTUx signals, andthen the signal clock of the distributed base station is restoredaccording to the FIFO (first in first out) status and the interfacesignals of the distributed base station are restored.

In transmitting the uplink signals, namely, when the data is sent to theBBU from the RRU, the process of processing signals are basically thesame to the process of the downlink signal transmission.

In the embodiments of the present invention, the OTUx signal frames inthe OTN system may include the Forward Error Correction (FEC). By usingthe FEC technology, the line error can be corrected. When the error rateis 10-5, it can be reduced to 10-15 after the FEC processing. The aboveerror rate after correction can meet the requirements on the error ratefor the interface of the distributed base station. As shown in FIG. 9,the frame structure of OTUx includes an overhead area, a payload area,and an FEC area. In the specific implementation process, differentinterface signals of the distributed base station may be placed intodifferent positions of the payload area. As the check redundant code,the FEC can further perform check and restoring based on thetransmission error including the payload so as to enhance the network.

Besides, the overhead area in the frame structure of the OTUx canprovide sufficient overhead management. In the direction of receivingthe signals, BIP-8 error statistics may be performed, and LOF and OOFalarms may be monitored and reported; in the direction of sending thesignals, the failure may be reported towards the downstream through theoverhead based on the received failure signals, the failure may bepositioned and indicated very clearly, thereby effectively improving theefficiency of operation and maintenance of the transmission network.

By using the signal transmission processing method and apparatus and thedistributed base station according to the present invention, OTNelectrical layer multiplexing is performed on at least one channel ofinterface signals of the distributed base station, electro-opticconversion is performed for the signals obtained through OTN electricallayer multiplexing to generate a channel of optical signals, and thesignals are transmitted. Therefore, multiple channels of interfacesignals of the distributed base station can be multiplexed into onechannel of optical signals, and the optical signals are transmittedbetween the BBU and the RRU of the distributed base station, therebyimproving the efficiency of signal transmission.

It should be noted that the above embodiments are merely used toillustrate the technical solutions of the present invention, but notintended to limit the scope of the present invention. Although thepresent invention is described in detail with reference to exemplaryembodiments, those skilled in the art should understand that: Anymodification or equivalent replacement made on the technical solutionsof the present invention without departing from the spirit and principleof the present invention should fall within the protection scope of thepresent invention.

What is claimed is:
 1. A method for transmitting an interface signal ofa distributed base station through an optical transport network,comprising: encapsulating at least one Common Public Radio Interface(CPRI) signal of the distributed base station into an optical transportunit x (OTUx) signal by adopting a Generic Mapping Procedure (GMP)mapping scheme, wherein the x represents a transmission capacity of theOTUx signal; and sending the OTUx signal.
 2. An apparatus fortransmitting an interface signal of a distributed base station,comprising: a processor and a non-transitory computer readable mediumhaving a plurality of computer executable instructions stored thereonwhich, when executed by the processor, cause the processor toencapsulate at least one Common Public Radio Interface (CPRI) signal ofthe distributed base station into an optical transport unit x (OTUx)signal by adopting a Generic Mapping Procedure (GMP) mapping scheme,wherein the x represents a transmission capacity of the OTUx signal; anda transmitter configured to send the OTUx signal.
 3. A method forreceiving an interface signal of a distributed base station through anoptical transport network, comprising: receiving an optical transportunit x (OTUx) signal, wherein the OTUx signal is multiplexed with atleast one Common Public Radio Interface (CPRI) signal of the distributedbase station through a Generic Mapping Procedure (GMP) mapping scheme,wherein the x represents a transmission capacity of the OTUx signal;de-encapsulating the OTUx signal to obtain the at least one CPRI signal.4. The method of claim 3, wherein a signal clock for each CPRI signal isobtained according to a first in first out (FIFO) status of a FIFOmemory.
 5. An apparatus for receiving an interface signal of adistributed base station through an optical transport network,comprising: a receiver configured to receive an optical transport unit x(OTUx) signal, wherein the OTUx signal bears at least one Common PublicRadio Interface (CPRI) signal of the distributed base stationencapsulated by adopting a Generic Mapping Procedure (GMP) mappingscheme, wherein the x represents a transmission capacity of the OTUxsignal; a processor and a non-transitory computer readable medium havinga plurality of computer executable instructions stored thereon which,when executed by the processor, cause the processor to demultiplex theOTUx signal to obtain the at least one CPRI signal.
 6. The apparatus ofclaim 5, wherein a signal clock for each CPRI signal is obtainedaccording to a first in first out (FIFO) status of a FIFO memory.
 7. Anapparatus for transmitting an interface signal of a distributed basestation, comprising: a first optical transport network (OTN) processingunit, coupled to a Base Band Unit (BBU) of the distributed base station;and a second OTN processing unit, coupled to the first OTN processingunit and to at least one Remote Radio Unit (RRU) of the distributed basestation; wherein the first OTN processing unit is configured toencapsulate at least one Common Public Radio Interface (CPRI) signalfrom the BBU into an optical transport unit x (OTUx) signal, and sendthe OTUx signal to the second OTN processing unit; wherein the at leastone CPRI signal from the BBU is encapsulated into the OTUx signal byadopting a Generic Mapping Procedure (GMP) mapping scheme, wherein the xrepresents a transmission capacity of the OTUx signal; wherein thesecond OTN processing unit is configured to de-encapsulate the OTUxsignal to obtain the at least one CPRI signal from the BBU, and send theobtained at least one CPRI signal from the BBU to the at least one RRU.8. The apparatus of claim 7, wherein a signal clock for each CPRI signalfrom the BBU is obtained according to a first in first out (FIFO) statusof a FIFO memory.
 9. The apparatus of claim 7, wherein: the second OTNprocessing unit is further configured to encapsulate at least one CommonPublic Radio Interface (CPRI) signal from the at least one RRU into anoptical transport unit y (OTUy) signal by adopting a GMP scheme, andsend the OTUy signal to the first OTN processing unit, wherein the yrepresents a transmission capacity of the OTUy signal; the first OTNprocessing unit is further configured to de-encapsulate the OTUy signalto obtain the at least one CPRI signal from the at least one RRU, andsend the obtained at least one CPRI signal from the at least one RRU tothe BBU.
 10. A method for transmitting interface signals of adistributed base station through an optical transport network,comprising: encapsulating multiple Common Public Radio Interface (CPRI)signals of the distributed base station into an optical transport unit x(OTUx) signal by adopting a Generic Mapping Procedure (GMP) mappingscheme, wherein the x represents a transmission capacity of the OTUxsignal; and sending the OTUx signal.
 11. An apparatus for transmittinginterface signals of a distributed base station, comprising: a processorand a non-transitory computer readable medium having a plurality ofcomputer executable instructions stored thereon which, when executed bythe processor, cause the processor to encapsulate multiple Common PublicRadio Interface (CPRI) signals of the distributed base station into anoptical transport unit x (OTUx) signal by adopting a Generic MappingProcedure (GMP) mapping scheme, wherein the x represents a transmissioncapacity of the OTUx signal; and a transmitter configured to send theOTUx signal.
 12. A method for receiving interface signals of adistributed base station through an optical transport network,comprising: receiving an optical transport unit x (OTUx) signal, whereinthe OTUx signal is multiplexed with multiple Common Public RadioInterface (CPRI) signal of the distributed base station through aGeneric Mapping Procedure (GMP) mapping scheme, wherein the x representsa transmission capacity of the OTUx signal; de-encapsulating the OTUxsignal to obtain the multiple the CPRI signals.
 13. An apparatus forreceiving interface signals of a distributed base station through anoptical transport network, comprising: a receiver configured to receivean optical transport unit x (OTUx) signal, wherein the OTUx signal bearsmultiple Common Public Radio Interface (CPRI) signal of the distributedbase station encapsulated by adopting a Generic Mapping Procedure (GMP)mapping scheme, wherein the x represents a transmission capacity of theOTUx signal; and a processor and a non-transitory computer readablemedium having a plurality of computer executable instructions storedthereon which, when executed by the processor, cause the processor todemultiplex the OTUx signal to obtain the multiple CPRI signals.
 14. Anapparatus for transmitting interface signals of a distributed basestation, comprising: a first optical transport network (OTN) processingunit, coupled to a Base Band Unit (BBU) of the distributed base station;and a second OTN processing unit, coupled to the first OTN processingunit and to multiple Remote Radio Units (RRUs) of the distributed basestation; wherein the first OTN processing unit is configured toencapsulate multiple Common Public Radio Interface (CPRI) signals fromthe BBU into an optical transport unit x (OTUx) signal, and send theOTUx signal to the second OTN processing unit; wherein the multiple CPRIsignals from the BBU is encapsulated into the OTUx signal by adopting aGeneric Mapping Procedure (GMP) mapping scheme, wherein the x representsa transmission capacity of the OTUx signal; and wherein the second OTNprocessing unit is configured to de-encapsulate the OTUx signal toobtain the multiple CPRI signals from the BBU, and send the obtainedmultiple CPRI signals from the BBU to the multiple RRUs.